/*
* Copyright (c) 1997, 2013, Oracle and/or its affiliates. All rights reserved.
* DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
*
* This code is free software; you can redistribute it and/or modify it
* under the terms of the GNU General Public License version 2 only, as
* published by the Free Software Foundation. Oracle designates this
* particular file as subject to the "Classpath" exception as provided
* by Oracle in the LICENSE file that accompanied this code.
*
* This code is distributed in the hope that it will be useful, but WITHOUT
* ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
* FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
* version 2 for more details (a copy is included in the LICENSE file that
* accompanied this code).
*
* You should have received a copy of the GNU General Public License version
* 2 along with this work; if not, write to the Free Software Foundation,
* Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
*
* Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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*/
package java.awt.datatransfer;
import java.awt.Toolkit;
import java.lang.ref.SoftReference;
import java.io.BufferedReader;
import java.io.File;
import java.io.InputStreamReader;
import java.io.IOException;
import java.net.URL;
import java.net.MalformedURLException;
import java.util.ArrayList;
import java.util.Collections;
import java.util.HashMap;
import java.util.HashSet;
import java.util.LinkedHashSet;
import java.util.List;
import java.util.Map;
import java.util.Objects;
import java.util.Set;
import sun.awt.AppContext;
import sun.awt.datatransfer.DataTransferer;
/**
* The SystemFlavorMap is a configurable map between "natives" (Strings), which
* correspond to platform-specific data formats, and "flavors" (DataFlavors),
* which correspond to platform-independent MIME types. This mapping is used
* by the data transfer subsystem to transfer data between Java and native
* applications, and between Java applications in separate VMs.
* <p>
*
* @since 1.2
*/
public final class SystemFlavorMap implements FlavorMap, FlavorTable {
/**
* Constant prefix used to tag Java types converted to native platform
* type.
*/
private static String JavaMIME = "JAVA_DATAFLAVOR:";
private static final Object FLAVOR_MAP_KEY = new Object();
/**
* Copied from java.util.Properties.
*/
private static final String keyValueSeparators = "=: \t\r\n\f";
private static final String strictKeyValueSeparators = "=:";
private static final String whiteSpaceChars = " \t\r\n\f";
/**
* The list of valid, decoded text flavor representation classes, in order
* from best to worst.
*/
private static final String[] UNICODE_TEXT_CLASSES = {
"java.io.Reader", "java.lang.String", "java.nio.CharBuffer", "\"[C\""
};
/**
* The list of valid, encoded text flavor representation classes, in order
* from best to worst.
*/
private static final String[] ENCODED_TEXT_CLASSES = {
"java.io.InputStream", "java.nio.ByteBuffer", "\"[B\""
};
/**
* A String representing text/plain MIME type.
*/
private static final String TEXT_PLAIN_BASE_TYPE = "text/plain";
/**
* A String representing text/html MIME type.
*/
private static final String HTML_TEXT_BASE_TYPE = "text/html";
/**
* Maps native Strings to Lists of DataFlavors (or base type Strings for
* text DataFlavors).
* Do not use the field directly, use getNativeToFlavor() instead.
*/
private final Map<String, LinkedHashSet<DataFlavor>> nativeToFlavor = new HashMap<>();
/**
* Accessor to nativeToFlavor map. Since we use lazy initialization we must
* use this accessor instead of direct access to the field which may not be
* initialized yet. This method will initialize the field if needed.
*
* @return nativeToFlavor
*/
private Map<String, LinkedHashSet<DataFlavor>> getNativeToFlavor() {
if (!isMapInitialized) {
initSystemFlavorMap();
}
return nativeToFlavor;
}
/**
* Maps DataFlavors (or base type Strings for text DataFlavors) to Lists of
* native Strings.
* Do not use the field directly, use getFlavorToNative() instead.
*/
private final Map<DataFlavor, LinkedHashSet<String>> flavorToNative = new HashMap<>();
/**
* Accessor to flavorToNative map. Since we use lazy initialization we must
* use this accessor instead of direct access to the field which may not be
* initialized yet. This method will initialize the field if needed.
*
* @return flavorToNative
*/
private synchronized Map<DataFlavor, LinkedHashSet<String>> getFlavorToNative() {
if (!isMapInitialized) {
initSystemFlavorMap();
}
return flavorToNative;
}
/**
* Maps a text DataFlavor primary mime-type to the native. Used only to store
* standard mappings registered in the flavormap.properties
* Do not use this field directly, use getTextTypeToNative() instead.
*/
private Map<String, LinkedHashSet<String>> textTypeToNative = new HashMap<>();
/**
* Shows if the object has been initialized.
*/
private boolean isMapInitialized = false;
/**
* An accessor to textTypeToNative map. Since we use lazy initialization we
* must use this accessor instead of direct access to the field which may not
* be initialized yet. This method will initialize the field if needed.
*
* @return textTypeToNative
*/
private synchronized Map<String, LinkedHashSet<String>> getTextTypeToNative() {
if (!isMapInitialized) {
initSystemFlavorMap();
// From this point the map should not be modified
textTypeToNative = Collections.unmodifiableMap(textTypeToNative);
}
return textTypeToNative;
}
/**
* Caches the result of getNativesForFlavor(). Maps DataFlavors to
* SoftReferences which reference LinkedHashSet of String natives.
*/
private final SoftCache<DataFlavor, String> nativesForFlavorCache = new SoftCache<>();
/**
* Caches the result getFlavorsForNative(). Maps String natives to
* SoftReferences which reference LinkedHashSet of DataFlavors.
*/
private final SoftCache<String, DataFlavor> flavorsForNativeCache = new SoftCache<>();
/**
* Dynamic mapping generation used for text mappings should not be applied
* to the DataFlavors and String natives for which the mappings have been
* explicitly specified with setFlavorsForNative() or
* setNativesForFlavor(). This keeps all such keys.
*/
private Set<Object> disabledMappingGenerationKeys = new HashSet<>();
/**
* Returns the default FlavorMap for this thread's ClassLoader.
*/
public static FlavorMap getDefaultFlavorMap() {
AppContext context = AppContext.getAppContext();
FlavorMap fm = (FlavorMap) context.get(FLAVOR_MAP_KEY);
if (fm == null) {
fm = new SystemFlavorMap();
context.put(FLAVOR_MAP_KEY, fm);
}
return fm;
}
private SystemFlavorMap() {
}
/**
* Initializes a SystemFlavorMap by reading flavormap.properties and
* AWT.DnD.flavorMapFileURL.
* For thread-safety must be called under lock on this.
*/
private void initSystemFlavorMap() {
if (isMapInitialized) {
return;
}
isMapInitialized = true;
BufferedReader flavormapDotProperties =
java.security.AccessController.doPrivileged(
new java.security.PrivilegedAction<BufferedReader>() {
public BufferedReader run() {
String fileName =
System.getProperty("java.home") +
File.separator +
"lib" +
File.separator +
"flavormap.properties";
try {
return new BufferedReader
(new InputStreamReader
(new File(fileName).toURI().toURL().openStream(), "ISO-8859-1"));
} catch (MalformedURLException e) {
System.err.println("MalformedURLException:" + e + " while loading default flavormap.properties file:" + fileName);
} catch (IOException e) {
System.err.println("IOException:" + e + " while loading default flavormap.properties file:" + fileName);
}
return null;
}
});
String url =
java.security.AccessController.doPrivileged(
new java.security.PrivilegedAction<String>() {
public String run() {
return Toolkit.getProperty("AWT.DnD.flavorMapFileURL", null);
}
});
if (flavormapDotProperties != null) {
try {
parseAndStoreReader(flavormapDotProperties);
} catch (IOException e) {
System.err.println("IOException:" + e + " while parsing default flavormap.properties file");
}
}
BufferedReader flavormapURL = null;
if (url != null) {
try {
flavormapURL = new BufferedReader(new InputStreamReader(new URL(url).openStream(), "ISO-8859-1"));
} catch (MalformedURLException e) {
System.err.println("MalformedURLException:" + e + " while reading AWT.DnD.flavorMapFileURL:" + url);
} catch (IOException e) {
System.err.println("IOException:" + e + " while reading AWT.DnD.flavorMapFileURL:" + url);
} catch (SecurityException e) {
// ignored
}
}
if (flavormapURL != null) {
try {
parseAndStoreReader(flavormapURL);
} catch (IOException e) {
System.err.println("IOException:" + e + " while parsing AWT.DnD.flavorMapFileURL");
}
}
}
/**
* Copied code from java.util.Properties. Parsing the data ourselves is the
* only way to handle duplicate keys and values.
*/
private void parseAndStoreReader(BufferedReader in) throws IOException {
while (true) {
// Get next line
String line = in.readLine();
if (line == null) {
return;
}
if (line.length() > 0) {
// Continue lines that end in slashes if they are not comments
char firstChar = line.charAt(0);
if (firstChar != '#' && firstChar != '!') {
while (continueLine(line)) {
String nextLine = in.readLine();
if (nextLine == null) {
nextLine = "";
}
String loppedLine =
line.substring(0, line.length() - 1);
// Advance beyond whitespace on new line
int startIndex = 0;
for(; startIndex < nextLine.length(); startIndex++) {
if (whiteSpaceChars.
indexOf(nextLine.charAt(startIndex)) == -1)
{
break;
}
}
nextLine = nextLine.substring(startIndex,
nextLine.length());
line = loppedLine+nextLine;
}
// Find start of key
int len = line.length();
int keyStart = 0;
for(; keyStart < len; keyStart++) {
if(whiteSpaceChars.
indexOf(line.charAt(keyStart)) == -1) {
break;
}
}
// Blank lines are ignored
if (keyStart == len) {
continue;
}
// Find separation between key and value
int separatorIndex = keyStart;
for(; separatorIndex < len; separatorIndex++) {
char currentChar = line.charAt(separatorIndex);
if (currentChar == '\\') {
separatorIndex++;
} else if (keyValueSeparators.
indexOf(currentChar) != -1) {
break;
}
}
// Skip over whitespace after key if any
int valueIndex = separatorIndex;
for (; valueIndex < len; valueIndex++) {
if (whiteSpaceChars.
indexOf(line.charAt(valueIndex)) == -1) {
break;
}
}
// Skip over one non whitespace key value separators if any
if (valueIndex < len) {
if (strictKeyValueSeparators.
indexOf(line.charAt(valueIndex)) != -1) {
valueIndex++;
}
}
// Skip over white space after other separators if any
while (valueIndex < len) {
if (whiteSpaceChars.
indexOf(line.charAt(valueIndex)) == -1) {
break;
}
valueIndex++;
}
String key = line.substring(keyStart, separatorIndex);
String value = (separatorIndex < len)
? line.substring(valueIndex, len)
: "";
// Convert then store key and value
key = loadConvert(key);
value = loadConvert(value);
try {
MimeType mime = new MimeType(value);
if ("text".equals(mime.getPrimaryType())) {
String charset = mime.getParameter("charset");
if (DataTransferer.doesSubtypeSupportCharset
(mime.getSubType(), charset))
{
// We need to store the charset and eoln
// parameters, if any, so that the
// DataTransferer will have this information
// for conversion into the native format.
DataTransferer transferer =
DataTransferer.getInstance();
if (transferer != null) {
transferer.registerTextFlavorProperties
(key, charset,
mime.getParameter("eoln"),
mime.getParameter("terminators"));
}
}
// But don't store any of these parameters in the
// DataFlavor itself for any text natives (even
// non-charset ones). The SystemFlavorMap will
// synthesize the appropriate mappings later.
mime.removeParameter("charset");
mime.removeParameter("class");
mime.removeParameter("eoln");
mime.removeParameter("terminators");
value = mime.toString();
}
} catch (MimeTypeParseException e) {
e.printStackTrace();
continue;
}
DataFlavor flavor;
try {
flavor = new DataFlavor(value);
} catch (Exception e) {
try {
flavor = new DataFlavor(value, null);
} catch (Exception ee) {
ee.printStackTrace();
continue;
}
}
final LinkedHashSet<DataFlavor> dfs = new LinkedHashSet<>();
dfs.add(flavor);
if ("text".equals(flavor.getPrimaryType())) {
dfs.addAll(convertMimeTypeToDataFlavors(value));
store(flavor.mimeType.getBaseType(), key, getTextTypeToNative());
}
for (DataFlavor df : dfs) {
store(df, key, getFlavorToNative());
store(key, df, getNativeToFlavor());
}
}
}
}
}
/**
* Copied from java.util.Properties.
*/
private boolean continueLine (String line) {
int slashCount = 0;
int index = line.length() - 1;
while((index >= 0) && (line.charAt(index--) == '\\')) {
slashCount++;
}
return (slashCount % 2 == 1);
}
/**
* Copied from java.util.Properties.
*/
private String loadConvert(String theString) {
char aChar;
int len = theString.length();
StringBuilder outBuffer = new StringBuilder(len);
for (int x = 0; x < len; ) {
aChar = theString.charAt(x++);
if (aChar == '\\') {
aChar = theString.charAt(x++);
if (aChar == 'u') {
// Read the xxxx
int value = 0;
for (int i = 0; i < 4; i++) {
aChar = theString.charAt(x++);
switch (aChar) {
case '0': case '1': case '2': case '3': case '4':
case '5': case '6': case '7': case '8': case '9': {
value = (value << 4) + aChar - '0';
break;
}
case 'a': case 'b': case 'c':
case 'd': case 'e': case 'f': {
value = (value << 4) + 10 + aChar - 'a';
break;
}
case 'A': case 'B': case 'C':
case 'D': case 'E': case 'F': {
value = (value << 4) + 10 + aChar - 'A';
break;
}
default: {
throw new IllegalArgumentException(
"Malformed \\uxxxx encoding.");
}
}
}
outBuffer.append((char)value);
} else {
if (aChar == 't') {
aChar = '\t';
} else if (aChar == 'r') {
aChar = '\r';
} else if (aChar == 'n') {
aChar = '\n';
} else if (aChar == 'f') {
aChar = '\f';
}
outBuffer.append(aChar);
}
} else {
outBuffer.append(aChar);
}
}
return outBuffer.toString();
}
/**
* Stores the listed object under the specified hash key in map. Unlike a
* standard map, the listed object will not replace any object already at
* the appropriate Map location, but rather will be appended to a List
* stored in that location.
*/
private <H, L> void store(H hashed, L listed, Map<H, LinkedHashSet<L>> map) {
LinkedHashSet<L> list = map.get(hashed);
if (list == null) {
list = new LinkedHashSet<>(1);
map.put(hashed, list);
}
if (!list.contains(listed)) {
list.add(listed);
}
}
/**
* Semantically equivalent to 'nativeToFlavor.get(nat)'. This method
* handles the case where 'nat' is not found in 'nativeToFlavor'. In that
* case, a new DataFlavor is synthesized, stored, and returned, if and
* only if the specified native is encoded as a Java MIME type.
*/
private LinkedHashSet<DataFlavor> nativeToFlavorLookup(String nat) {
LinkedHashSet<DataFlavor> flavors = getNativeToFlavor().get(nat);
if (nat != null && !disabledMappingGenerationKeys.contains(nat)) {
DataTransferer transferer = DataTransferer.getInstance();
if (transferer != null) {
LinkedHashSet<DataFlavor> platformFlavors =
transferer.getPlatformMappingsForNative(nat);
if (!platformFlavors.isEmpty()) {
if (flavors != null) {
// Prepending the platform-specific mappings ensures
// that the flavors added with
// addFlavorForUnencodedNative() are at the end of
// list.
platformFlavors.addAll(flavors);
}
flavors = platformFlavors;
}
}
}
if (flavors == null && isJavaMIMEType(nat)) {
String decoded = decodeJavaMIMEType(nat);
DataFlavor flavor = null;
try {
flavor = new DataFlavor(decoded);
} catch (Exception e) {
System.err.println("Exception \"" + e.getClass().getName() +
": " + e.getMessage() +
"\"while constructing DataFlavor for: " +
decoded);
}
if (flavor != null) {
flavors = new LinkedHashSet<>(1);
getNativeToFlavor().put(nat, flavors);
flavors.add(flavor);
flavorsForNativeCache.remove(nat);
LinkedHashSet<String> natives = getFlavorToNative().get(flavor);
if (natives == null) {
natives = new LinkedHashSet<>(1);
getFlavorToNative().put(flavor, natives);
}
natives.add(nat);
nativesForFlavorCache.remove(flavor);
}
}
return (flavors != null) ? flavors : new LinkedHashSet<>(0);
}
/**
* Semantically equivalent to 'flavorToNative.get(flav)'. This method
* handles the case where 'flav' is not found in 'flavorToNative' depending
* on the value of passes 'synthesize' parameter. If 'synthesize' is
* SYNTHESIZE_IF_NOT_FOUND a native is synthesized, stored, and returned by
* encoding the DataFlavor's MIME type. Otherwise an empty List is returned
* and 'flavorToNative' remains unaffected.
*/
private LinkedHashSet<String> flavorToNativeLookup(final DataFlavor flav,
final boolean synthesize) {
LinkedHashSet<String> natives = getFlavorToNative().get(flav);
if (flav != null && !disabledMappingGenerationKeys.contains(flav)) {
DataTransferer transferer = DataTransferer.getInstance();
if (transferer != null) {
LinkedHashSet<String> platformNatives =
transferer.getPlatformMappingsForFlavor(flav);
if (!platformNatives.isEmpty()) {
if (natives != null) {
// Prepend the platform-specific mappings to ensure
// that the natives added with
// addUnencodedNativeForFlavor() are at the end of
// list.
platformNatives.addAll(natives);
}
natives = platformNatives;
}
}
}
if (natives == null) {
if (synthesize) {
String encoded = encodeDataFlavor(flav);
natives = new LinkedHashSet<>(1);
getFlavorToNative().put(flav, natives);
natives.add(encoded);
LinkedHashSet<DataFlavor> flavors = getNativeToFlavor().get(encoded);
if (flavors == null) {
flavors = new LinkedHashSet<>(1);
getNativeToFlavor().put(encoded, flavors);
}
flavors.add(flav);
nativesForFlavorCache.remove(flav);
flavorsForNativeCache.remove(encoded);
} else {
natives = new LinkedHashSet<>(0);
}
}
return new LinkedHashSet<>(natives);
}
/**
* Returns a <code>List</code> of <code>String</code> natives to which the
* specified <code>DataFlavor</code> can be translated by the data transfer
* subsystem. The <code>List</code> will be sorted from best native to
* worst. That is, the first native will best reflect data in the specified
* flavor to the underlying native platform.
* <p>
* If the specified <code>DataFlavor</code> is previously unknown to the
* data transfer subsystem and the data transfer subsystem is unable to
* translate this <code>DataFlavor</code> to any existing native, then
* invoking this method will establish a
* mapping in both directions between the specified <code>DataFlavor</code>
* and an encoded version of its MIME type as its native.
*
* @param flav the <code>DataFlavor</code> whose corresponding natives
* should be returned. If <code>null</code> is specified, all
* natives currently known to the data transfer subsystem are
* returned in a non-deterministic order.
* @return a <code>java.util.List</code> of <code>java.lang.String</code>
* objects which are platform-specific representations of platform-
* specific data formats
*
* @see #encodeDataFlavor
* @since 1.4
*/
@Override
public synchronized List<String> getNativesForFlavor(DataFlavor flav) {
LinkedHashSet<String> retval = nativesForFlavorCache.check(flav);
if (retval != null) {
return new ArrayList<>(retval);
}
if (flav == null) {
retval = new LinkedHashSet<>(getNativeToFlavor().keySet());
} else if (disabledMappingGenerationKeys.contains(flav)) {
// In this case we shouldn't synthesize a native for this flavor,
// since its mappings were explicitly specified.
retval = flavorToNativeLookup(flav, false);
} else if (DataTransferer.isFlavorCharsetTextType(flav)) {
retval = new LinkedHashSet<>(0);
// For text/* flavors, flavor-to-native mappings specified in
// flavormap.properties are stored per flavor's base type.
if ("text".equals(flav.getPrimaryType())) {
LinkedHashSet<String> textTypeNatives =
getTextTypeToNative().get(flav.mimeType.getBaseType());
if (textTypeNatives != null) {
retval.addAll(textTypeNatives);
}
}
// Also include text/plain natives, but don't duplicate Strings
LinkedHashSet<String> textTypeNatives =
getTextTypeToNative().get(TEXT_PLAIN_BASE_TYPE);
if (textTypeNatives != null) {
retval.addAll(textTypeNatives);
}
if (retval.isEmpty()) {
retval = flavorToNativeLookup(flav, true);
} else {
// In this branch it is guaranteed that natives explicitly
// listed for flav's MIME type were added with
// addUnencodedNativeForFlavor(), so they have lower priority.
retval.addAll(flavorToNativeLookup(flav, false));
}
} else if (DataTransferer.isFlavorNoncharsetTextType(flav)) {
retval = getTextTypeToNative().get(flav.mimeType.getBaseType());
if (retval == null || retval.isEmpty()) {
retval = flavorToNativeLookup(flav, true);
} else {
// In this branch it is guaranteed that natives explicitly
// listed for flav's MIME type were added with
// addUnencodedNativeForFlavor(), so they have lower priority.
retval.addAll(flavorToNativeLookup(flav, false));
}
} else {
retval = flavorToNativeLookup(flav, true);
}
nativesForFlavorCache.put(flav, retval);
// Create a copy, because client code can modify the returned list.
return new ArrayList<>(retval);
}
/**
* Returns a <code>List</code> of <code>DataFlavor</code>s to which the
* specified <code>String</code> native can be translated by the data
* transfer subsystem. The <code>List</code> will be sorted from best
* <code>DataFlavor</code> to worst. That is, the first
* <code>DataFlavor</code> will best reflect data in the specified
* native to a Java application.
* <p>
* If the specified native is previously unknown to the data transfer
* subsystem, and that native has been properly encoded, then invoking this
* method will establish a mapping in both directions between the specified
* native and a <code>DataFlavor</code> whose MIME type is a decoded
* version of the native.
* <p>
* If the specified native is not a properly encoded native and the
* mappings for this native have not been altered with
* <code>setFlavorsForNative</code>, then the contents of the
* <code>List</code> is platform dependent, but <code>null</code>
* cannot be returned.
*
* @param nat the native whose corresponding <code>DataFlavor</code>s
* should be returned. If <code>null</code> is specified, all
* <code>DataFlavor</code>s currently known to the data transfer
* subsystem are returned in a non-deterministic order.
* @return a <code>java.util.List</code> of <code>DataFlavor</code>
* objects into which platform-specific data in the specified,
* platform-specific native can be translated
*
* @see #encodeJavaMIMEType
* @since 1.4
*/
@Override
public synchronized List<DataFlavor> getFlavorsForNative(String nat) {
LinkedHashSet<DataFlavor> returnValue = flavorsForNativeCache.check(nat);
if (returnValue != null) {
return new ArrayList<>(returnValue);
} else {
returnValue = new LinkedHashSet<>();
}
if (nat == null) {
for (String n : getNativesForFlavor(null)) {
returnValue.addAll(getFlavorsForNative(n));
}
} else {
final LinkedHashSet<DataFlavor> flavors = nativeToFlavorLookup(nat);
if (disabledMappingGenerationKeys.contains(nat)) {
return new ArrayList<>(flavors);
}
final LinkedHashSet<DataFlavor> flavorsWithSynthesized =
nativeToFlavorLookup(nat);
for (DataFlavor df : flavorsWithSynthesized) {
returnValue.add(df);
if ("text".equals(df.getPrimaryType())) {
String baseType = df.mimeType.getBaseType();
returnValue.addAll(convertMimeTypeToDataFlavors(baseType));
}
}
}
flavorsForNativeCache.put(nat, returnValue);
return new ArrayList<>(returnValue);
}
private static Set<DataFlavor> convertMimeTypeToDataFlavors(
final String baseType) {
final Set<DataFlavor> returnValue = new LinkedHashSet<>();
String subType = null;
try {
final MimeType mimeType = new MimeType(baseType);
subType = mimeType.getSubType();
} catch (MimeTypeParseException mtpe) {
// Cannot happen, since we checked all mappings
// on load from flavormap.properties.
}
if (DataTransferer.doesSubtypeSupportCharset(subType, null)) {
if (TEXT_PLAIN_BASE_TYPE.equals(baseType))
{
returnValue.add(DataFlavor.stringFlavor);
}
for (String unicodeClassName : UNICODE_TEXT_CLASSES) {
final String mimeType = baseType + ";charset=Unicode;class=" +
unicodeClassName;
final LinkedHashSet<String> mimeTypes =
handleHtmlMimeTypes(baseType, mimeType);
for (String mt : mimeTypes) {
DataFlavor toAdd = null;
try {
toAdd = new DataFlavor(mt);
} catch (ClassNotFoundException cannotHappen) {
}
returnValue.add(toAdd);
}
}
for (String charset : DataTransferer.standardEncodings()) {
for (String encodedTextClass : ENCODED_TEXT_CLASSES) {
final String mimeType =
baseType + ";charset=" + charset +
";class=" + encodedTextClass;
final LinkedHashSet<String> mimeTypes =
handleHtmlMimeTypes(baseType, mimeType);
for (String mt : mimeTypes) {
DataFlavor df = null;
try {
df = new DataFlavor(mt);
// Check for equality to plainTextFlavor so
// that we can ensure that the exact charset of
// plainTextFlavor, not the canonical charset
// or another equivalent charset with a
// different name, is used.
if (df.equals(DataFlavor.plainTextFlavor)) {
df = DataFlavor.plainTextFlavor;
}
} catch (ClassNotFoundException cannotHappen) {
}
returnValue.add(df);
}
}
}
if (TEXT_PLAIN_BASE_TYPE.equals(baseType))
{
returnValue.add(DataFlavor.plainTextFlavor);
}
} else {
// Non-charset text natives should be treated as
// opaque, 8-bit data in any of its various
// representations.
for (String encodedTextClassName : ENCODED_TEXT_CLASSES) {
DataFlavor toAdd = null;
try {
toAdd = new DataFlavor(baseType +
";class=" + encodedTextClassName);
} catch (ClassNotFoundException cannotHappen) {
}
returnValue.add(toAdd);
}
}
return returnValue;
}
private static final String [] htmlDocumntTypes =
new String [] {"all", "selection", "fragment"};
private static LinkedHashSet<String> handleHtmlMimeTypes(String baseType,
String mimeType) {
LinkedHashSet<String> returnValues = new LinkedHashSet<>();
if (HTML_TEXT_BASE_TYPE.equals(baseType)) {
for (String documentType : htmlDocumntTypes) {
returnValues.add(mimeType + ";document=" + documentType);
}
} else {
returnValues.add(mimeType);
}
return returnValues;
}
/**
* Returns a <code>Map</code> of the specified <code>DataFlavor</code>s to
* their most preferred <code>String</code> native. Each native value will
* be the same as the first native in the List returned by
* <code>getNativesForFlavor</code> for the specified flavor.
* <p>
* If a specified <code>DataFlavor</code> is previously unknown to the
* data transfer subsystem, then invoking this method will establish a
* mapping in both directions between the specified <code>DataFlavor</code>
* and an encoded version of its MIME type as its native.
*
* @param flavors an array of <code>DataFlavor</code>s which will be the
* key set of the returned <code>Map</code>. If <code>null</code> is
* specified, a mapping of all <code>DataFlavor</code>s known to the
* data transfer subsystem to their most preferred
* <code>String</code> natives will be returned.
* @return a <code>java.util.Map</code> of <code>DataFlavor</code>s to
* <code>String</code> natives
*
* @see #getNativesForFlavor
* @see #encodeDataFlavor
*/
@Override
public synchronized Map<DataFlavor,String> getNativesForFlavors(DataFlavor[] flavors)
{
// Use getNativesForFlavor to generate extra natives for text flavors
// and stringFlavor
if (flavors == null) {
List<DataFlavor> flavor_list = getFlavorsForNative(null);
flavors = new DataFlavor[flavor_list.size()];
flavor_list.toArray(flavors);
}
Map<DataFlavor, String> retval = new HashMap<>(flavors.length, 1.0f);
for (DataFlavor flavor : flavors) {
List<String> natives = getNativesForFlavor(flavor);
String nat = (natives.isEmpty()) ? null : natives.get(0);
retval.put(flavor, nat);
}
return retval;
}
/**
* Returns a <code>Map</code> of the specified <code>String</code> natives
* to their most preferred <code>DataFlavor</code>. Each
* <code>DataFlavor</code> value will be the same as the first
* <code>DataFlavor</code> in the List returned by
* <code>getFlavorsForNative</code> for the specified native.
* <p>
* If a specified native is previously unknown to the data transfer
* subsystem, and that native has been properly encoded, then invoking this
* method will establish a mapping in both directions between the specified
* native and a <code>DataFlavor</code> whose MIME type is a decoded
* version of the native.
*
* @param natives an array of <code>String</code>s which will be the
* key set of the returned <code>Map</code>. If <code>null</code> is
* specified, a mapping of all supported <code>String</code> natives
* to their most preferred <code>DataFlavor</code>s will be
* returned.
* @return a <code>java.util.Map</code> of <code>String</code> natives to
* <code>DataFlavor</code>s
*
* @see #getFlavorsForNative
* @see #encodeJavaMIMEType
*/
@Override
public synchronized Map<String,DataFlavor> getFlavorsForNatives(String[] natives)
{
// Use getFlavorsForNative to generate extra flavors for text natives
if (natives == null) {
List<String> nativesList = getNativesForFlavor(null);
natives = new String[nativesList.size()];
nativesList.toArray(natives);
}
Map<String, DataFlavor> retval = new HashMap<>(natives.length, 1.0f);
for (String aNative : natives) {
List<DataFlavor> flavors = getFlavorsForNative(aNative);
DataFlavor flav = (flavors.isEmpty())? null : flavors.get(0);
retval.put(aNative, flav);
}
return retval;
}
/**
* Adds a mapping from the specified <code>DataFlavor</code> (and all
* <code>DataFlavor</code>s equal to the specified <code>DataFlavor</code>)
* to the specified <code>String</code> native.
* Unlike <code>getNativesForFlavor</code>, the mapping will only be
* established in one direction, and the native will not be encoded. To
* establish a two-way mapping, call
* <code>addFlavorForUnencodedNative</code> as well. The new mapping will
* be of lower priority than any existing mapping.
* This method has no effect if a mapping from the specified or equal
* <code>DataFlavor</code> to the specified <code>String</code> native
* already exists.
*
* @param flav the <code>DataFlavor</code> key for the mapping
* @param nat the <code>String</code> native value for the mapping
* @throws NullPointerException if flav or nat is <code>null</code>
*
* @see #addFlavorForUnencodedNative
* @since 1.4
*/
public synchronized void addUnencodedNativeForFlavor(DataFlavor flav,
String nat) {
Objects.requireNonNull(nat, "Null native not permitted");
Objects.requireNonNull(flav, "Null flavor not permitted");
LinkedHashSet<String> natives = getFlavorToNative().get(flav);
if (natives == null) {
natives = new LinkedHashSet<>(1);
getFlavorToNative().put(flav, natives);
}
natives.add(nat);
nativesForFlavorCache.remove(flav);
}
/**
* Discards the current mappings for the specified <code>DataFlavor</code>
* and all <code>DataFlavor</code>s equal to the specified
* <code>DataFlavor</code>, and creates new mappings to the
* specified <code>String</code> natives.
* Unlike <code>getNativesForFlavor</code>, the mappings will only be
* established in one direction, and the natives will not be encoded. To
* establish two-way mappings, call <code>setFlavorsForNative</code>
* as well. The first native in the array will represent the highest
* priority mapping. Subsequent natives will represent mappings of
* decreasing priority.
* <p>
* If the array contains several elements that reference equal
* <code>String</code> natives, this method will establish new mappings
* for the first of those elements and ignore the rest of them.
* <p>
* It is recommended that client code not reset mappings established by the
* data transfer subsystem. This method should only be used for
* application-level mappings.
*
* @param flav the <code>DataFlavor</code> key for the mappings
* @param natives the <code>String</code> native values for the mappings
* @throws NullPointerException if flav or natives is <code>null</code>
* or if natives contains <code>null</code> elements
*
* @see #setFlavorsForNative
* @since 1.4
*/
public synchronized void setNativesForFlavor(DataFlavor flav,
String[] natives) {
Objects.requireNonNull(natives, "Null natives not permitted");
Objects.requireNonNull(flav, "Null flavors not permitted");
getFlavorToNative().remove(flav);
for (String aNative : natives) {
addUnencodedNativeForFlavor(flav, aNative);
}
disabledMappingGenerationKeys.add(flav);
nativesForFlavorCache.remove(flav);
}
/**
* Adds a mapping from a single <code>String</code> native to a single
* <code>DataFlavor</code>. Unlike <code>getFlavorsForNative</code>, the
* mapping will only be established in one direction, and the native will
* not be encoded. To establish a two-way mapping, call
* <code>addUnencodedNativeForFlavor</code> as well. The new mapping will
* be of lower priority than any existing mapping.
* This method has no effect if a mapping from the specified
* <code>String</code> native to the specified or equal
* <code>DataFlavor</code> already exists.
*
* @param nat the <code>String</code> native key for the mapping
* @param flav the <code>DataFlavor</code> value for the mapping
* @throws NullPointerException if nat or flav is <code>null</code>
*
* @see #addUnencodedNativeForFlavor
* @since 1.4
*/
public synchronized void addFlavorForUnencodedNative(String nat,
DataFlavor flav) {
Objects.requireNonNull(nat, "Null native not permitted");
Objects.requireNonNull(flav, "Null flavor not permitted");
LinkedHashSet<DataFlavor> flavors = getNativeToFlavor().get(nat);
if (flavors == null) {
flavors = new LinkedHashSet<>(1);
getNativeToFlavor().put(nat, flavors);
}
flavors.add(flav);
flavorsForNativeCache.remove(nat);
}
/**
* Discards the current mappings for the specified <code>String</code>
* native, and creates new mappings to the specified
* <code>DataFlavor</code>s. Unlike <code>getFlavorsForNative</code>, the
* mappings will only be established in one direction, and the natives need
* not be encoded. To establish two-way mappings, call
* <code>setNativesForFlavor</code> as well. The first
* <code>DataFlavor</code> in the array will represent the highest priority
* mapping. Subsequent <code>DataFlavor</code>s will represent mappings of
* decreasing priority.
* <p>
* If the array contains several elements that reference equal
* <code>DataFlavor</code>s, this method will establish new mappings
* for the first of those elements and ignore the rest of them.
* <p>
* It is recommended that client code not reset mappings established by the
* data transfer subsystem. This method should only be used for
* application-level mappings.
*
* @param nat the <code>String</code> native key for the mappings
* @param flavors the <code>DataFlavor</code> values for the mappings
* @throws NullPointerException if nat or flavors is <code>null</code>
* or if flavors contains <code>null</code> elements
*
* @see #setNativesForFlavor
* @since 1.4
*/
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